Classifications

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  • H04N19/00—Methods or arrangements for coding, decoding, compressing or decompressing digital video signals
  • H04N19/10—Methods or arrangements for coding, decoding, compressing or decompressing digital video signals using adaptive coding
  • H04N19/102—Methods or arrangements for coding, decoding, compressing or decompressing digital video signals using adaptive coding characterised by the element, parameter or selection affected or controlled by the adaptive coding
  • H04N19/103—Selection of coding mode or of prediction mode
  • H04N19/109—Selection of coding mode or of prediction mode among a plurality of temporal predictive coding modes
• • H—ELECTRICITY
  • H04—ELECTRIC COMMUNICATION TECHNIQUE
  • H04N—PICTORIAL COMMUNICATION, e.g. TELEVISION
  • H04N19/00—Methods or arrangements for coding, decoding, compressing or decompressing digital video signals
  • H04N19/10—Methods or arrangements for coding, decoding, compressing or decompressing digital video signals using adaptive coding
  • H04N19/102—Methods or arrangements for coding, decoding, compressing or decompressing digital video signals using adaptive coding characterised by the element, parameter or selection affected or controlled by the adaptive coding
  • H04N19/103—Selection of coding mode or of prediction mode
  • H04N19/11—Selection of coding mode or of prediction mode among a plurality of spatial predictive coding modes
• • G—PHYSICS
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  • G06N—COMPUTING ARRANGEMENTS BASED ON SPECIFIC COMPUTATIONAL MODELS
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  • G06N3/02—Neural networks
  • G06N3/04—Architecture, e.g. interconnection topology
  • G06N3/048—Activation functions
• • G—PHYSICS
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• • H—ELECTRICITY
  • H04—ELECTRIC COMMUNICATION TECHNIQUE
  • H04N—PICTORIAL COMMUNICATION, e.g. TELEVISION
  • H04N19/00—Methods or arrangements for coding, decoding, compressing or decompressing digital video signals
  • H04N19/10—Methods or arrangements for coding, decoding, compressing or decompressing digital video signals using adaptive coding
  • H04N19/169—Methods or arrangements for coding, decoding, compressing or decompressing digital video signals using adaptive coding characterised by the coding unit, i.e. the structural portion or semantic portion of the video signal being the object or the subject of the adaptive coding
  • H04N19/17—Methods or arrangements for coding, decoding, compressing or decompressing digital video signals using adaptive coding characterised by the coding unit, i.e. the structural portion or semantic portion of the video signal being the object or the subject of the adaptive coding the unit being an image region, e.g. an object
  • H04N19/176—Methods or arrangements for coding, decoding, compressing or decompressing digital video signals using adaptive coding characterised by the coding unit, i.e. the structural portion or semantic portion of the video signal being the object or the subject of the adaptive coding the unit being an image region, e.g. an object the region being a block, e.g. a macroblock
• • H—ELECTRICITY
  • H04—ELECTRIC COMMUNICATION TECHNIQUE
  • H04N—PICTORIAL COMMUNICATION, e.g. TELEVISION
  • H04N19/00—Methods or arrangements for coding, decoding, compressing or decompressing digital video signals
  • H04N19/50—Methods or arrangements for coding, decoding, compressing or decompressing digital video signals using predictive coding
  • H04N19/593—Methods or arrangements for coding, decoding, compressing or decompressing digital video signals using predictive coding involving spatial prediction techniques
• • H—ELECTRICITY
  • H04—ELECTRIC COMMUNICATION TECHNIQUE
  • H04N—PICTORIAL COMMUNICATION, e.g. TELEVISION
  • H04N19/00—Methods or arrangements for coding, decoding, compressing or decompressing digital video signals
  • H04N19/60—Methods or arrangements for coding, decoding, compressing or decompressing digital video signals using transform coding
  • H04N19/61—Methods or arrangements for coding, decoding, compressing or decompressing digital video signals using transform coding in combination with predictive coding
• • H—ELECTRICITY
  • H04—ELECTRIC COMMUNICATION TECHNIQUE
  • H04N—PICTORIAL COMMUNICATION, e.g. TELEVISION
  • H04N19/00—Methods or arrangements for coding, decoding, compressing or decompressing digital video signals
  • H04N19/70—Methods or arrangements for coding, decoding, compressing or decompressing digital video signals characterised by syntax aspects related to video coding, e.g. related to compression standards

Definitions

• the present application is concerned with an improved intra-prediction mode concept for block-wise picture coding such as usable in a video codec such as HEVC or any successor of HEVC.
• Intra-prediction modes are widely used in picture and video coding.
• intra- prediction modes compete with other prediction modes such as inter-prediction modes such as motion-compensated prediction modes.
• intra-prediction modes a current block is predicted on the basis of neighboring samples, i.e. samples already encoded as far as the encoder side is concerned, and already decoded as far as the decoder side is concerned.
• neighboring sample values are extrapolated into the current block so as to form a prediction signal for the current block with the prediction residual being transmitted in the datastream for the current block. The better the prediction signal is, the lower the prediction residual is and, accordingly, a lower number of bits is necessary to code the prediction residual.
• the set of supported intra-prediction modes should be able to provide a good prediction signal, i.e. a prediction signal resulting in a low prediction residual.
• the present application seeks to provide an intra-prediction mode concept allowing for a more efficient compression of a block-wise picture codec if using the improved intra- prediction mode concept.
• an improved compression efficiency is achieved by letting a block-wise picture codec support a set of intra-prediction modes according to which the intra-prediction signal for a current block of a picture is determined by applying a set of neighboring samples of the current block onto a neural network.
• This set may form the plurality of intra-prediction modes supported completely or merely a proper subset thereof.
• the plurality of intra-prediction modes supported one is selected for the current block and the current block is predicted using the one intra- prediction mode, i.e. the selected one.
• the datastream may be provided with an index for the current block which indicates the selected intra-prediction mode.
• Providing a block- wise picture codec with more than one neural network-based intra-prediction modes between which a selection is performed for a current block enables designing these neural network-based intra-prediction modes so as to find for a certain block with an increased likelihood a prediction signal of low prediction error.
• the neural network intra- prediction mode design may be performed in such a manner that, if side information for intra-prediction mode selection is spent, this side information overhead may be kept low. This is made feasible by the fact that the intra-prediction mode design is free to generate the neural network-based intra-prediction modes in a manner of mutually different frequency of selection among intra-predicted picture blocks.
• an index pointing to the selected intra-prediction mode may be coded using variable length code or using entropy coding and the neural network-based intra-prediction modes may be designed in a manner so that their frequencies of selection or frequency distribution is adapted to the variable length code such, or their frequency distribution is adapted to the underlying sample statistics of the entropy code such that the mean signalization overhead for the mode selection among the intra-prediction modes is reduced or minimized.
• a second aspect of the present application is that, additionally or alternatively to the spending of neural network-based intra-prediction modes, the mode selection may be rendered more effective by the usage of a neural network dedicated to determine a rank or a probability value for each of the set of intra-prediction modes by applying a set of neighboring samples thereonto with the rank or probability value being used for the selection of one intra-prediction mode out of the plurality of intra-prediction modes including or coinciding with the set of intra-prediction modes.
• the side information overhead for select- ing among the intra-prediction modes may be left off completely, or may be rendered more efficient by using the neural network.
• the present application provides many embodiments for appropriately determining parameters thereof.
• FIG. 1 shows a schematic block diagram illustrating an encoder for encoding a picture into a datastream as a general example where embodiments of the present application may be implemented
• Fig. 2 shows a block diagram of a more specific example for an encoder according to Fig.
• Fig. 3 shows a schematic block diagram illustrating a decoder fitting to the encoder of Fig.
• Fig. 4 shows a block diagram of a more specific example of a decoder of Fig. 3, which fits to the encoder of Fig. 2;
• Fig. 5 shows a schematic diagram illustrating the mode of operation in encoder and decoder according to embodiments of the present application with respect to processing a block using intra-prediction;
• Fig. 6 shows a schematic block diagram illustrating a decoder in accordance with an em- bodiment of the present application comprising several neural network-based intra- prediction modes;
• Fig. 7a shows a schematic diagram illustrating the mode of operation of an encoder and a decoder in accordance with an embodiment supporting neural network-based in- tra-prediction modes and a neural network-based ordering of these modes with transmitting within the datastream an index into an ordered list of neural network- based intra-prediction modes along with a fleck indicating whether the intra- prediction mode to be used is member of the set of neural network-based intra- prediction modes or not.
• the index may be coded using variable length coding so as to take advantage of the different frequency of being de- termined by determination 90;
• Fig. 7b shows a schematic diagram differing from Fig. 7a in that the fleck signalization is not used
• Fig. 7c shows a schematic diagram differing from 7b in that the mode ordering is not controlled using a neural network
• Fig. 7d shows a schematic diagram differing from 7a in that the neural network assistance in mode signalization is used for controlling the probability distribution estimation in entropy en/decoding rather than for mode ordering;
• Fig. 8 shows an apparatus for designing a set of neural network-based intra-prediction modes in accordance with an embodiment
• Fig. 9a shows a schematic diagram illustrating the mode of operation of encoder and decoder in accordance with an embodiment according to which a neural network is used for ordering supported intra-prediction modes irrespective of whether neural network-based or not
• Fig. 9b shows a schematic diagram differing from Fig. 9a in that the neural network base is used for controlling the probabilities distribution estimation for entropy de/encoding of the index into the set of supported intra-prediction modes;
• Fig. 10 shows an apparatus for designing a neural network for assisting and selecting among a set of intra-prediction mode for block-based picture coding in accordance with an embodiment.
• FIG. 1 shows an apparatus for block-wise encoding a picture 10 into a datastream 12.
• the apparatus is indicated using reference sign 14 and may be a still picture encoder or a video encoder.
• picture 10 may be a current picture out of a video 16 when the encoder 14 is configured to encode video 16 including picture 10 into datastream 12, or encoder 14 may encode picture 10 into datastream 12 exclusively.
• encoder 14 performs the encoding in a block-wise manner or block-base. To this, encoder 14 subdivides picture 10 into blocks a team in units of which encoder 14 encodes picture 10 into datastream 12. Examples of possible subdivisions of picture 10 into blocks 18 are set out in more detail below. Generally, the subdivision may end-up into blocks 18 of constant size suggest an array of blocks arranged in rows and columns or into blocks 18 of different block sizes such as by use of a hierarchical multi-tree subdivi- sioning with starting the multi-tree subdivisioning from the whole picture area of picture 10 or from a pre-partitioning of picture 10 into an array of tree blocks wherein these examples shall not be treated as excluding other possible ways of subdivisioning picture 10 into blocks 18.
• encoder 14 is a predictive encoder configured to predictively encode picture 10 into datastream 12. For a certain block 18 this means that encoder 14 determines a prediction signal for block 18 and encodes the prediction residual, i.e. the prediction error at which the prediction signal deviates from the actual picture content within block 18, into datastream 12.
• Encoder 14 may support different prediction modes so as to derive the prediction signal for a certain block 18.
• the prediction modes which are of importance in the following embodiments, are intra-prediction modes according to which the inner of block 18 is predicted spatially from neighboring, already encoded samples of picture 10.
• the encoding of picture 10 into datastream 12 and, accordingly, the corresponding decoding procedure may be based on a certain coding order 20 defined among blocks 18. For instance, the coding order 20 may traverse blocks 18 in a raster scan order such as row- wise from top to bottom with traversing each row from left to right, for instance.
• raster scan ordering may be applied within each hierarchy level, wherein a depth-first traversal order may be applied, i.e. leaf notes within a block of a certain hierarchy level may precede blocks of the same hierarchy level having the same parent block according to coding order 20.
• neighboring, already encoded samples of a block 18 may be located usually at one or more sides of block 18. In case of the examples presented herein, for instance, neighboring, already encoded samples of a block 18 are located to the top of, and to the left of block 18.
• Intra-prediction modes may not be the only ones supported by encoder 14.
• encoder 14 may also support intra- prediction modes according to which a block 18 is temporarily predicted from a previously encoded picture of video 16.
• Such an intra-prediction mode may be a motion- compensated prediction mode according to which a motion vector is signaled for such a block 18 indicating a relative spatial offset of the portion from which the prediction signal of block 18 is to be derived as a copy.
• other non-intra- prediction modes may be available as well such as inter-view prediction modes in case of encoder 14 being a multi-view encoder, or non-predictive modes according to which the inner of block 18 is coded as is, i.e. without any prediction.
• Fig. 2 shows a possible implementation of encoder 14 of Fig. 1 , namely one where the encoder is configured to use transform coding for encoding the prediction residual although this is nearly an example and the present application is not restricted to that sort of prediction residual coding.
• encoder 14 comprises a subtractor 22 configured to subtract from the inbound signal, i.e. picture 10 or, on a block basis, current block 18, the corresponding prediction signal 24 so as to obtain the prediction residual signal 26 which is then encoded by a prediction residual encoder 28 into a datastream 12.
• the prediction residual encoder 28 is composed of a lossy encoding stage 28a and a lossless encoding stage 28b.
• the lossy stage 28a receives the prediction residual signal 26 and comprises a quantizer 30 which quantizes the samples of the prediction residual signal 26.
• the lossy encoding stage 28a comprises a transform stage 32 connected between subtractor 22 and quantizer 30 so as to transform such a spectrally decomposed prediction residual 26 with a quantization of quantizer 30 taking place on the transformed coefficients where presenting the residual signal 26.
• the transform may be a DCT, DST, FFT, Hadamard transform or the like.
• the transformed and quantized prediction residual signal 34 is then subject to lossless coding by the lossless encoding stage 28b which is an entropy coder entropy coding quantized prediction residual signal 34 into datastream 12.
• Encoder 14 further comprises the prediction residu- al signal reconstruction stage 36 connected to the output of quantizer 30 so as to reconstruct from the transformed and quantized prediction residual signal 34 the prediction residual signal in a manner also available at the decoder, i.e. taking the coding loss is quantizer 30 into account.
• the prediction residual reconstruction stage 36 comprises a dequantizer 38 which perform the inverse of the quantization of quantizer 30, fol- lowed by an inverse transformer 40 which performs the inverse transformation relative to the transformation performed by transformer 32 such as the inverse of the spectral decomposition such as the inverse to any of the above-mentioned specific transformation examples, encoder 14 comprises an adder 42 which adds the reconstructed prediction residual signal as output by inverse transformer 40 and the prediction signal 24 so as to output a reconstructed signal, i.e. reconstruct examples. This output is fed into a predictor 44 of encoder 14 which then determines the prediction signal 24 based thereon. It is predictor 44 which supports all the prediction modes already discussed above with respect to Fig. 1.
• Fig. 2 also illustrates that in case of encoder 14 being a video encoder, encoder 14 may also comprise an in-loop filter 46 with filters completely reconstructed pictures which, after having been filtered, form reference pictures for predictor 44 with respect to inter- predicted block.
• encoder 14 operates block-based.
• the block bases of interest is the one subdividing picture 10 into blocks for which the intra-prediction mode is selected out of a set or plurality of intra-prediction modes supported by predictor 44 or encoder 14, respectively, and the selected intra-prediction mode performed individually.
• Other sorts of blocks into which picture 10 is subdivided may, however, exist as well.
• the above-mentioned decision whether picture 10 is inter-coded or intra-coded may be done at a granularity or in units of blocks deviating from blocks 18.
• the inter/intra mode decision may be performed at a level of coding blocks into which picture 10 is subdivided, and each coding block is subdivided into prediction blocks.
• Prediction blocks with encoding blocks for which it has been decided that intra-prediction is used are each subdivided to an intra-prediction mode decision. To this, for each of these prediction blocks, it is decided as to which supported intra- prediction mode should be used for the respective prediction block.
• These prediction blocks will form blocks 18 which are of interest here.
• Prediction blocks within coding blocks associated with inter-prediction would be treated differently by predictor 44. They would be inter- predicted from reference pictures by determining a motion vector and copying the prediction signal for this block from a location in the reference picture pointed to by the motion vector.
• Another block subdivisioning pertains the subdivisioning into transform blocks at units of which the transformations by transformer 32 and inverse transformer 40 are performed. Transformed blocks may, for instance, be the result of further subdivisioning coding blocks.
• the examples set out herein should not be treated as being limiting and other examples exist as well.
• the subdivisioning into coding blocks may, for instance, use multi-tree subdivisioning, and prediction blocks and/or transform blocks may be obtained by further subdividing coding blocks using multi-tree subdivisioning, as well.
• a decoder or apparatus for block-wise decoding fitting to the encoder 14 of Fig. 1 is depicted in Fig. 3.
• This decoder 54 does the opposite of encoder 14, i.e. it decodes from datastream 12 picture 10 in a block-wise manner and supports, to this end, a plurality of intra-prediction modes. All the other possibilities discussed above with respect to Fig. 1 are valid for the decoder 54, too.
• decoder 54 may be a still picture decoder or a video decoder and all the prediction modes and prediction possibilities are supported by decoder 54 as well.
• encoder 14 chooses or selects coding decisions according to some optimization suggest, for instance, in order to minimize some cost function which may depend on coding rate and/or coding distortion.
• One of these coding options or coding parameters may involve a selection of the intra-prediction mode to be used for a current block 18 among available or supported intra-prediction modes.
• the selected intra-prediction mode may then be signaled by encoder 14 for current block 18 within datastream 12 with decoder 54 redoing the selection using this signalization in datastream 12 for block 18.
• decoder 54 may be a predictive decoder operating on a block-bases and besides intra-prediction modes, de- coder 54 may support other prediction modes such as inter-prediction modes in case of, for instance, decoder 54 being a video decoder, in decoding, decoder 54 may also use the coding order 20 discussed with respect to Fig.
• the description of the mode of operation of encoder 14 shall also apply to decoder 54 as far the subdivision of picture 10 into blocks is concerned, for instance, as far as prediction is concerned and as far as the coding of the prediction residual is concerned. Differences lie in the fact that encoder 14 chooses, by optimization, some coding options or coding parameters and signals within, or inserts into, datastream 12 the coding parameters which are then derived from the datastream 12 by decoder 54 so as to redo the prediction, subdivision and so forth.
• Fig. 4 shows a possible implementation of the decoder 54 of Fig. 3, namely one fitting to the implementation of encoder 14 of Fig. 1 as shown in Fig. 2.
• the same reference signs, provided with an apostrophe, are used in Fig. 4 in order to indicate these elements.
• adder 42 ' , optional in-loop filter 46 ' and predictor 44' are connected into a prediction loop in the same manner that they are in encoder of Fig. 2. The reconstructed, i.e.
• dequantized and retransformed prediction residual signal applied to added 42 ' is derived by a sequence of entropy decoder 56 which inverses the entropy encoding of entropy encoder 28b, followed by the residual signal reconstruction stage 36 ' which is composed of dequantizer 38 ' and inverse transformer 40 ' just as it is the case on encoding side.
• the decoder ' s output is the reconstruction of picture 10.
• the reconstruction of picture 10 may be available directly at the output of adder 42 ' or, alternatively, at the output of in-loop filter 46 ' .
• Some post-filter may be arranged at the decoder ' s output in order to subject the reconstruction of picture 10 to some post-filtering in order to improve the picture quality, but this option is not depicted in Fig. 4.
• the description brought forward above with respect to Fig. 2 shall be valid for Fig. 4 as well with the exception that merely the encoder performs the optimization tasks and the associated decisions with respect to coding options.
• all the description with respect to block-subdivisioning, prediction, dequantization and re- transforming is also valid for the decoder 54 of Fig. 4.
• block 18 may have any shape. It may be, for instance, of rectangular or quadratic shape. Moreover, although the above description of the mode of operation of encoder 14 and decoder 54 often mentioned a "current block" 18 it is clear that encoder 14 and decoder 54 act accordingly for each block for which an intra- prediction mode is to be selected. As described above, there may be other blocks as well, but the following description focuses on those blocks 18 into which picture 10 is subdivided, for which an intra-prediction mode is to be selected.
• Fig. 5 shows a current block 18, i.e. a block currently to be encoded or decoded.
• Fig. 5 shows a set 60 of neighboring samples 62, i.e. samples 62 with spatially neighbor block 18.
• the samples 64 within block 18 are to be predicted.
• the prediction signal to be derived is, thus, a prediction for each sample 64 within block 18.
• a plurality 66 of prediction modes are available for each block 18 and if block 18 is to be intra-predicted, this plurality 66 of modes merely comprises inter-prediction modes.
• a selection 68 is performed at encoder and decoder side in order to determine one of the intra-prediction modes out of the plurality 66 to be used to predict 71 the prediction signal for block 18 on the basis of the neighboring sample set 60.
• the embodiments described further below differ with respect to the available intra-prediction modes 66 and the mode of operation with respect to selection 68 suggest, for instance, whether side information is set in the datastream 12 with respect to selection 68 with respect to block 18 or not. The description of these embodiments, how- ever, starts with a concrete description providing mathematical details.
• the selection for a certain block 18 to be intra-predicted is associated with corresponding side information signalization 70 and the datastream and the plurality 66 of intra-prediction modes comprises a set 72 of neural network-based intra-prediction modes as well as a set 74 of further intra-prediction mode of heuristic design.
• One of the intra-prediction modes of mode 74 may, for instance, be a DC prediction mode according to which some mean value is determined on the basis of the neighboring sample set 60 and this mean value is assigned to all samples 64 within block 18.
• set 74 may comprise inter-prediction modes which may be called angular inter- prediction modes according to which sample values of the neighboring sample set 60 are copied into block 18 along a certain intra-prediction direction with this intra-prediction direction differing among such angular intra-prediction modes.
• Fig. 5 shows that the datastream 12 comprises, in addition to the optionally present side information 70 concerning the selection 68 out of the plurality 66 of intra-prediction modes, a portion 76 into which the prediction residual encoded which coding may, as discussed above, optionally involve transform coding with quantization in transform domain.
• Fig. 6 shows the general mode of operation for an intra-prediction block at encoder and decoder.
• Fig. 6 shows block 18 along with the neighboring samples set 60 on the basis of which the intra-prediction is performed.
• this set 60 may vary among the intra-prediction modes of the plurality 66 of intra-prediction modes in terms of cardinality, i.e. the number of samples of set 60 actually used according to the respective intra-prediction mode for determining the prediction signal for block 18. This is, however, for ease of understanding, not depicted in Fig. 6.
• FIG. 6 shows that encoder and decoder have one neural network 80 0 to 80 B-1 for each of the neural network-based intra-prediction modes of set 72.
• Set 60 is applied to the respective neural network so as to derive the corresponding intra-prediction mode among set 72.
• Fig. 6 rather representatively shows one block 82 as providing on the basis of the input, namely the set 60 of neighboring samples, the one or more prediction signals of the one or more intra-prediction modes of set 74, e.g. the DC mode prediction signal and/or angular intra-prediction mode prediction signal.
• the specific embodiment set out hereinafter also provides encoder and decoder with another neural network 84 which is dedicated to provide a probability value for each neural network-based intra-prediction mode within set 72 on the basis of a set 86 of neighboring samples which may or may not coincide with set 60.
• the probability values thus provided when the neural network 84 assists in rendering the side information 70 for the mode selection more effective.
• the probability values provided by the neural network 84 enable to use the variable length code within the side information 70 as an index into an ordered list of intra-prediction modes ordered according to the probability values output by neural network 84 for the neural network-based intra-prediction modes within set 72, thereby optimizing or reducing the code rate for the side information 70.
• the mode selection 68 is effectively performed depending on both, the probability values provided by the further neural network 84 as well as the side information 70 within datastream 12.
• B c l? be a block of a video frame, i.e. block 18.
• B has M pixels.
• im be the content of a video signal on B.
• im be the content of a video signal on B.
• B We regard im as an element of E3 ⁇ 4 M .
• B rec c ⁇ ? of B that has L pixels and on which an already reconstructed image tec e is available, i.e. sample sets 60 and 86 although they may alternatively differ.
• F intra-prediction-function
• HEVC intra predictions and train our predictions as complementary predictions.
• a typical hybrid video coding standard usually supports several blocks shapes into which the given block B can be partitioned.
• section 1.1 we shall describe how to deal with the first item.
• section1.2 it is described how to handle items 2 to 3.
• section1 .4 it is described how to take item 4 into account.
• section 1.5 it is described how to deal with the last item.
• a data driven approach to determine unknown parameters that are used in a video codec is usually set up as an optimization algorithm that tries to minimize a predefined loss function on a given set of training examples. Typically, for a numerical optimization algorithm to work in practice, the latter loss function should satisfy some smoothness requirements.
• a video encoder like HEVC performs best when it makes its decisions my minimizing the Rate-Distortion costs D + ⁇ ⁇ R.
• D is the reconstruction error of the decoded video signal
• R is the rate, i.e. the number of bits needed to code the video signal.
• ⁇ e R is a Lagrangian Parameter that depends on the chosen Quantization Parameter.
• the true function D + ⁇ ⁇ R is typically very complex and is not given by a closed expression on can feed a data driven optimization algorithm with. Thus, we approximate either the whole function D + ⁇ ⁇ R or at least the rate function R by a piecewise smooth function.
• H R M ⁇ R which are piecewise smooth such that H(res) serves as a good approximation of D(res) + ⁇ ⁇ R(res) and such that R(res) serves as a good approximation of R(res).
• D + AR Rate-Distortion values
• the functions in (2) define the neural network 80 0 - 80 K B -1 in Fig. 6.
• G ⁇ (rec): G u (rec, B ), Again, an example is given in section 1 .3 with the function of (4) representing neural network 84 of Fig. 6.
• This function for instance, defines a VLC code length distribution used for side information 70. i.e. the code lengths assocaited by side information 70 with cad ponite more of set 72. Then we define
• M$ H (rec) shall model the number of bits needed to signal the fc-th intra mode that we train.
• each of these functions consists of a sequence of compositions of functions which are either: 1 ) An affine transofrmation Aff or 2) A non-linear activation function Act.
• Each linear map L: R m ⁇ R n is completely determined by a matrix in R nxm , i.e. corresponds uniquely to a vector 0 L E R m n .
• Each affine function Aff: R m ⁇ W 1 is thus completely determined by m ⁇ n + n weights, i.e. by a vector 0 e M to' " +ti .
• Aff Q for the unique affine transformation that corresponds to ⁇ in the aforementioned way.
• (Act(x))i denotes the i-th component of Act(x) and x t denotes the i-th component of x.
• p R ⁇ R my be of the form
• T (m 1 - n 1 + ) + (m 2 ⁇ n 2 + n 2 ) + ⁇ + (m k ⁇ n k + n fc ).
• F Q would, thus, describe a neural network 80i parametrized using paramters ⁇ . It would be a sequence of linear functions Aff . and non-linear functions p, which, in the present example, are applied alternatingly in the sequence, wherein the parameters ⁇ comprise the linear function weights in Aff ..
• the pairs of a linear function Aff®. followed by non-linear function p would represent a neuron layer, for example, such as the j-th layer, with the number of predecessor nodes preceding this neuron layer j in feed-forward direction of the neural network being determined by dimension m of Aff e .
• each row of Af / ej incorpartes the weights controlling as to how strong a signal strength respectively activation of each of the m predecessor neurons is forwarded to the respective neuron of the neuron layer j which corresponds to the respective row.
• p controlls for each neuron of neuron layer j the non-linear mapping of its linear combination of forwarded predecessor neuron activations onto its own activation.
• the number of neurons per layer may vary.
• the number of nuron layers k may vary among the various neural networks 80 j , i.e. for different j. Note, that the non-linear function might vary per neurion layer or even per neuron or at some other units.
• T (m' 1 ⁇ n + n ) + (m' 2 ⁇ n' 2 + n' 2 ) + ⁇ ⁇ + (m' k , ⁇ n' kl + n' k> ).
• T e e and K B ⁇ N are as in (3). Then, for ⁇ e
• G ⁇ Affo kl p Aff kl ⁇ p Afh kl ⁇ 0 - ° P ° Aff l .
• the number of neuron layers k' of neural network 84 may differ from one or more of the number of neuron layers k of neural networks 80,.
• Tf ix can consist of the DC- or Planar-prediction of HEVC and angular predictions defined according to HEVC; all those predictions may also include a preliminary smoothing of the reconstructed samples.
• Tf ix can consist of the DC- or Planar-prediction of HEVC and angular predictions defined according to HEVC; all those predictions may also include a preliminary smoothing of the reconstructed samples.
• each B ⁇ ec c z 2 is a neighborhood of B t .
• B ec is a union of two rectangles left and above B t .
• B max e ⁇ £ such that B £ e J5 max for each i e ⁇ 1, ...,S ⁇ .
• ⁇ ( ⁇ £) be the power set of ⁇ .
• B ⁇ ⁇ we assume that a set
• ⁇ ⁇ ⁇ , ⁇ ⁇ ⁇ by minimizing or at least making small the expression ⁇ ia Loss ⁇ ,lomi (im i( req, ⁇ , ⁇ "),
• the decoder has at its disposal fixed numbers K B , T e M, functions F B ; R L x M r ⁇ K M , namely 80 t ... 80 (CB _ 1) and G B : R L x R T ⁇ R 8 , namely 84, as well as weights Q 1 , ... , ® KB G R T and a weight ⁇ e M T , where the latter weights are determined in advance by a training algorithm that was described in the previous section.
• step 2 the decoder proceeds for the given block 10 as in the underlying hybrid video coding standard.
• step 2 the decoder applies the function G$, i.e. 84, defined according to (4), to the reconstructed image rec.
• G$ (x , ... , % fashion)
• the standard is changed in a way such that the decoder defines a number m ⁇ ⁇ 1, ... , K B ⁇ by exactly one of the following tow options: (i) The decoder defines a probability distribution P G B (rec) on the set ⁇ 1, ... , K B ] by
• ⁇ (/) ⁇ is the minimal number such that one has x fei+! > x k for all fc ⁇ ⁇ 1, ... , K B ⁇ ⁇ ( ⁇ ) ⁇ .
• the apparatus 54 supports a plurality of intra-prediction modes comprising, at least, a set 72 of intra-prediction modes according to which the intra-prediction signal for a current block 18 of the picture 10 is de- termined by applying a first set 60 of neighboring samples of the current block 18 onto a neural network 80,.
• the apparatus 54 is configured to select 68 for the current block 18 one intra-prediction mode out of the plurality 66 of intra-prediction modes and predicts 71 the current block 18 using the one intra-prediction mode, namely using the corresponding neural network 80 m having been selected.
• decoder 54 does not use, and does not comprise, the further neural network 84.
• the decoder 54 could decode from datastream 12 an index for block 18 using a variable length code, the code length of which are indicated in M B , and the decoder 54 would perform the selection 68 based on this index.
• the index would be part of the side information 70.
• the de- coder 54 may alternatively derive a ranking among the set 72 of neural network-based intra-prediction modes depending on a first portion of the datastream which relates to a neighborhood of the current block 18 in order to obtain an ordered list of intra-prediction modes with selecting the intra-prediction mode finally to be used out of the ordered list of intra-prediction modes depending on a second portion of the datastream other than the first portion.
• the "first portion” may, for instance, relate to a coding parameter or prediction parameter related to one or more block neighboring current block 18.
• the "second portion” may then be an index, for instance, pointing into, or being an index of, the neural network-based intra-prediction mode set 72.
• the decoder 54 comprises the further neural network 84 which deter- mines, for each intra-prediction mode of the set 72 of intra-prediction modes, a probability value by applying set 86 of neighboring samples thereonto and ordering these probability values in order to determine a rank for each intra-prediction mode of set 72, thereby obtaining an ordered list of intra-prediction modes.
• An index in the datastream 12 as part of side information 70 is then used as an index into the ordered list.
• this index may be coded using variable length code for which M B indicates the code length.
• decoder 54 may use the just-mentioned probability values determined by the further neural network 84 for each neural network-based intra-prediction mode of set 72 so as to efficiently perform entropy coding of the index into set 72.
• the symbol alphabet of this index which is part of the side information 70 and used as an index into set 72, would comprise a symbol or value for each of the modes within set 72, and the probability values provided by neural network 84 would, in case of neural network 84 design according to the above description, provide probability values which would lead to efficient entropy coding in that these probability values closely represent the actual symbol statistics.
• arithmetic coding could be used, for instance, or probability inter- val partitioning entropy (PIPE) coding.
• Each neural network 80 is once advantageously parametrized for encoder and decoder in accordance with, for example, the above description in sections 1 and 2, derives the prediction signal for the current block 18 without any additional guidance in the datastream.
• the existence of other intra-prediction modes besides the neural network-based ones in set 72 is optional. They have been indicated above by set 74.
• one possible way of selecting set 60 i.e. the set of neighboring samples forming the input for the intra-prediction 71 , may be selected such that this set 60 is the same for the intra-prediction modes of set 74, i.e.
• set 60 for the neural network-based intra-prediction modes being larger in terms of the number of neighboring samples included in set 60 and influencing the intra-prediction 71.
• the cardinality of set 60 may be larger for neural network-based intra-prediction modes 72 compared to the other modes of set 74.
• set 60 of any intra-prediction mode of set 74 may merely comprise neighboring samples along a one-dimensional line extending alongside to sides of block 18 such as the left hand one and the upper one.
• Set 60 of the neural network-based intra-prediction modes may cover an L-shaped portion extending alongside the just-mentioned sides of block 18 but being wider than just one-sample wide as set 60 for the intra-prediction modes of set 74.
• the side information 70 conveyed in the datastream 12 to an intra-predicted block 18 may comprise a fleck which generally indicates whether the selected intra-prediction mode for block 18 is member of set 72 or member of set 74. This fleck is, however, merely optional with side information 70 indicating, for instance, an index into a whole plurality 66 of intra-prediction modes including both sets 72 and 74.
• the just-discussed alternatives are, in the following, briefly discussed with respect to the Figs. 7a to 7d.
• the Figs define both, decoder and encoder concurrently, namely in terms of their functionality with respect to an intra-predicted block 18.
• the differences between the encoder mode of operation and the decoder mode of operation with respect to an in- tra-coded block 18 is, on the one hand, the fact that the encoder performs all or at least some of the intra-prediction modes 66 available so as to determine at 90 a best one in terms of, for instance, some cost function minimizing sense, and that the encoder forms data stream 12, i.e., codes date there into, while the decoder derives the data therefrom by decoding and reading, respectively.
• a flag 70a within the side information 70 for block 18 indicates whether the intra-prediction mode determined to be the best mode for block 18 by the encoder in step 90, is within set 72, i.e., is neural network based intra- prediction mode, or within set 74, i.e., one of the non-neural network based intra- prediction modes.
• the encoder inserts flag 70a into data stream 12 accordingly, while the decoder retrieves it therefrom.
• Fig. 7a assumes that the determined intra-prediction mode 92 is within set 72.
• the separate neural network 84 determines a probability value for each neural network based intra-prediction mode of set 72 and using these probability values set 72 or, to be more precise, the neural network based intra-prediction modes therein are ordered according to their probability values such as in descending order of their probability values, thereby resulting into an ordered list 94 of intra-prediction modes.
• An index 70b being part of the side information 70 is then coded by the encoder into data stream 12 and decoded therefrom by the decoder.
• the decoder accordingly, is able to determine which set of sets 72 and 74.
• the intra-prediction mode to be used for block 18 is located in, and to perform the ordering 96 of set 72 in case of the intra-prediction mode to be used being located in set 72.
• Fig. 7b shows an alternative according to which the flag 70a is not present in data stream 12.
• the ordered list 94 would not only comprise the intra-prediction modes of set 72, but also intra-prediction modes of set 74.
• the index within side information 70 would be an index into this greater ordered list and indicate the determined intra-prediction mode, i.e., the one determined be optimization 90.
• the ranking between intra-prediction modes of set 72 relative to the intra-prediction modes of set 74 may be determined by other means such as inevitably arranging the neural network based intra-prediction modes of set 72 to precede the modes of set 74 in the order list 94 or to arrange them alternatingly relative to each other. That is, the decoder is able to derive the index from data stream 12, use the index 70 as in index into the order list 94 with deriving the order list 94 from the plurality of intra-prediction modes 66 using the probability values output by neural network 84.
• Fig. 7c shows a further variant. Fig.
• Fig. 7c show a case of not using flag 70a, but the flag could be used alternatively.
• the issue which Fig. 7c is directed pertains to the possibility that neither encoder nor decoder uses neural network 84. Rather, the ordering 96 is derived by other means such as coding parameters conveyed within data stream 12 with respect to one or more neighboring blocks 18, i.e., portions 98 of a data stream 12 which pertains to such one or more neighboring blocks.
• Fig. 7d shows a further variant of Fig. 7a, namely the one according to which the index 70b is coded using entropy coding and decoded from data stream 12 using entropy decoding, commonly denoted using reference sign 100.
• the sample statistics or the probability distribution used for the entropy coding 100 is controlled by the probability values output by neural network 84 as explained above, this renders the entropy coding of index 70b very efficient.
• set 74 modes may not be present. Accordingly, the respective module 82 may be missing and flag 70a would be unnecessary anyway.
• the mode selection 68 at the encoder and decoder could be synchronized to each other even without any explicit signaling 70, i.e., without spending any side information. Rather, the selection could be derived from other means such as by taking inevitably the first one of the ordered list 94, or by deriving the index into the order list 94 on the basis of coding parameters relating to one or more neighboring blocks.
• Fig. 8 shows an apparatus for designing the set of intra- prediction modes of set 72 to be used for the block-based picture coding.
• the apparatus 108 comprises a parameterizable network 109 which inherits or comprises parameteriza- ble versions of neural networks 80 0 to 80 E as well as neural network 84.
• a parameterizable network 109 which inherits or comprises parameteriza- ble versions of neural networks 80 0 to 80 E as well as neural network 84.
• Fig. 8 depicted as individual units, i.e., neural network 84 0 for providing the probability value for neural network based intra-prediction mode 0 to neural network 84 K B-I for providing the probability value associated with the neural network based intra-prediction mode K B .i .
• the parameters 1 1 1 for parametrizing neural networks 84 and the parameters 1 13 for parametrizing neural networks 80 0 to 80 K B-I are input or applied to respective parameter inputs of these neural networks by an updater 1 10.
• Apparatus 108 has access to a reservoir or a plurality of picture test blocks 1 14 along with corresponding neighboring samples sets 1 16. Pairs of these blocks 1 14 and their associated neighboring sample sets 1 16 are sequentially used by apparatus 108.
• a current picture test block 1 14 is applied to parameterizable neural network 109 so that neural networks 80 provide a prediction signal 1 18 for each neural network based intra-prediction mode of set 72, and each neural network 80 provides a probability value for each of these modes. To this end, these neural networks use their current parameters 1 1 1 and 1 13.
• F® B (rec) is the prediction residual 1 18 for mode B and the probability value is G$ fl (rec) is the probability value 120.
• G$ fl (rec) is the probability value 120.
• cost estimators 122 computed the cost estimates as indicated on the left and right hand sides of the inequality in section 1 .2. That is, here, the cost estimators 122 also used, for each mode, the corresponding probability value 120. This needs not, however, to be case as already discussed above.
• the cost estimate is in any case a sum of two add- ins, one of which is an estimate of the coding cost for the prediction residual indicated as the term with R in the above inequality, and another add-in estimating the coding costs for indicating the mode.
• the cost estimators 122 In order to compute the estimate for the coding cost related to the prediction residual, the cost estimators 122 also obtain the original content of the current picture test block 1 14.
• the neural networks 80 and 84 had at their inputs applied thereto the corresponding neighboring sample sets 1 16.
• the cost estimate 124 as output by cost estimators 122 is received by a minimum cost selector 126 which determines the mode minimizing or having minimum cost estimate associated therewith, in the above mathematical notation, this has been k$ pt .
• the updater receives this optimum mode and uses a coding cost function having a first add in forming residual rate estimate depending on the prediction signal 1 18 obtained for the intra-prediction mode of lowest coding estimate, and a second add-in forming a mode signaling side information rate estimate depending on the prediction signal and the probability value obtained for the intra-prediction mode of lowest coding cost estimate as indicated by selector 126. As indicated above, this may be done using a gradient distant.
• the coding cost function is, thus, differentiable and in the above mathematical representation an example of this function was given in equation 5.
• the second add-in relating to the mode signaling side information rate estimate computed the cross entropy for the intra-prediction mode of lowest coding cost estimate.
• the updater 1 10 seeks to update parameters 1 1 1 and 1 13 so as to reduce the cod- ing cost function and then these updated parameters 1 1 1 and 1 13 are used by the pa- rameterizable neural network 109 so as to process the next picture test block of the plurality 1 12.
• the updater 1 10 seeks to update parameters 1 1 1 and 1 13 so as to reduce the cod- ing cost function and then these updated parameters 1 1 1 and 1 13 are used by the pa- rameterizable neural network 109 so as to process the next picture test block of the plurality 1 12.
• Fig. 9a seeks to outline the mode of operation of an encoder and a decoder in accordance with an embodiment wherein the description thereof is provided in a manner focusing on the differences to the description brought forward above with respect to Fig. 7a.
• the plurality 66 of supported intra-prediction modes may or may not comprise neural network-based intra-prediction modes and may or may not comprise non-neural network-based intra-prediction modes.
• the neural network 84 computes, on the basis of the neighboring sample set 86, probability values for the supported intra- prediction modes 66 so that the plurality 66 of intra-prediction modes may be turned into the ordered list 94.
• the index 70 within datastream 12 for block 18 points into this ordered list 94.
• the neural network 84 thus, assists in lowering the side information rate to be spent for the intra-prediction mode signalization.
• Fig. 9b shows an alternative to Fig. 9a in that instead of the ordering, entropy de/encoding 100 of the index 70 is used with controlling the probability or simple statistics thereof, i.e. controlling the entropy probability distribution for entropy de/encoding in en/decoder, ac- cording to the probability values determined for the neural network 84 for each mode of plurality 66.
• Fig. 10 shows an apparatus for designing or parametrizing neural network 84. It is, thus, an apparatus 08 for designing a neural network for assisting in selecting among a set 66 of intra-prediction modes.
• an apparatus 08 for each mode of set 66 there is a corresponding neural network block together forming neural network 84 and the parametrizable neural network 109 of apparatus 108 is merely parametrizable with respect these blocks.
• the prediction signal computer 170 For each mode, there is also the prediction signal computer 170 which needs, however, not to be parametrizable according to Fig. 10.
• the minimum cost selector 126 selects the mode of the minimum cost estimate and the updater 1 10 updates the parameters 1 1 1 for the neural 84.
• FIG. 7a to 7d The following is noted with respect to the description of Figs. 7a to 7d and 9a and 9b.
• a common feature of the embodiments of Figs. 9a and 9b which is also used by some of the embodiments of Figs. 7a to 7d was the fact that the probability values of the neurai net- work values in order to improve or reduce the overhead associated with the side information 70 for signaling the mode determined on the encoder side at the optimization process 90 to the decoder.
• the embodiments of Figs. 9a and 9b may be varied to the extent that no side information 70 is spent in datastream 12 with respect to the mode selection at all.
• the probability values output by neural network 84 for each mode may be used to synchronize the mode selection between encoder and decoder inevitably. In that case, there would be no optimization decision 90 at the encoder side with respect to the mode selection. Rather, the mode to be used among set 66 would be determined on encoder and decoder side in the same manner.
• a similar statement is true with respect to corresponding embodiments of Figs. 7a to 7d when varied so as to not use any side information 70 in datastream 12. Back to the embodiments of Figs.
• the dependency on the probability values may not only affect the coding of the side information 70 into datastream 12 using, for instance, a respective variable length coding of an index into the ordered list or using entropy en/decoding with a probability distribution estimation depending on the neural network ' s probability values, but also the optimization step 90: here, the code rate for transmitting side information 70 may be taken into account and may, thus, influence the determination 90.
• aspects have been described in the context of an apparatus, it is clear that these aspects also represent a description of the corresponding method, where a block or device corresponds to a method step or a feature of a method step. Analogously, aspects described in the context of a method step also represent a description of a corresponding block or item or feature of a corresponding apparatus.
• Some or all of the method steps may be executed by (or using) a hardware apparatus, like for example, a microprocessor, a programmable computer or an electronic circuit, in some embodiments, one or more of the most important method steps may be executed by such an apparatus.
• the inventive encoded data stream can be stored on a digital storage medium or can be transmitted on a transmission medium such as a wireless transmission medium or a wired transmission medium such as the Internet.
• a digital storage medium for example a floppy disk, a DVD, a Blu-Ray, a CD, a ROM, a PROM, an EPROM, an EEPROM or a FLASH memory, having electronically readable control signals stored thereon, which cooperate (or are capable of cooperating) with a programmable computer system such that the respective method is performed. Therefore, the digital storage medium may be computer readable.
• Some embodiments according to the invention comprise a data carrier having electronically readable control signals, which are capable of cooperating with a programmable computer system, such that one of the methods described herein is performed.
• embodiments of the present invention can be implemented as a computer program product with a program code, the program code being operative for performing one of the methods when the computer program product runs on a computer.
• the program code may for example be stored on a machine readable carrier.
• inventions comprise the computer program for performing one of the methods described herein, stored on a machine readable carrier.
• an embodiment of the inventive method is, therefore, a computer program having a program code for performing one of the methods described herein, when the computer program runs on a computer.
• a further embodiment of the inventive methods is, therefore, a data carrier (or a digital storage medium, or a computer-readable medium) comprising, recorded thereon, the computer program for performing one of the methods described herein.
• the data carrier, the digital storage medium or the recorded medium are typically tangible and/or non- transitionary.
• a further embodiment of the inventive method is, therefore, a data stream or a sequence of signals representing the computer program for performing one of the methods described herein.
• the data stream or the sequence of signals may for example be configured to be transferred via a data communication connection, for example via the Internet.
• a further embodiment comprises a processing means, for example a computer, or a pro- grammable logic device, configured to or adapted to perform one of the methods described herein.
• a processing means for example a computer, or a pro- grammable logic device, configured to or adapted to perform one of the methods described herein.
• a further embodiment comprises a computer having installed thereon the computer program for performing one of the methods described herein.
• a further embodiment according to the invention comprises an apparatus or a system configured to transfer (for example, electronically or optically) a computer program for performing one of the methods described herein to a receiver.
• the receiver may, for example, be a computer, a mobile device, a memory device or the like.
• the apparatus or sys- tern may, for example, comprise a file server for transferring the computer program to the receiver.
• a programmable logic device for example a field programmable gate array
• a field programmable gate array may cooperate with a microprocessor in order to perform one of the methods described herein.
• the methods are preferably performed by any hardware apparatus.
• the apparatus described herein may be implemented using a hardware apparatus, or using a computer, or using a combination of a hardware apparatus and a computer.
• the apparatus described herein, or any components of the apparatus described herein, may be implemented at least partially in hardware and/or in software.
• the methods described herein may be performed using a hardware apparatus, or using a computer, or using a combination of a hardware apparatus and a computer.

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